Sex-linked gene traffic underlies the acquisition of sexually dimorphic UV color vision in Heliconius butterflies

Abstract

AbstractButterflies have photoreceptor cells that are sensitive to the ultraviolet part of the spectrum due to ultraviolet-sensitive rhodopsin (UVRh), a gene that has been duplicated in the Heliconius genus. In individuals expressing UVRh1 and UVRh2, electrophysiological and behavioral studies demonstrate that these opsin proteins enable discrimination of UV wavelengths. This behavioral trait varies between species, being absent in H. melpomene and limited to females in H. erato. To identify the evolutionary origins of this trait, we first examined UV color vision in H. charithonia, a species related to H. erato in the sara/sapho group. We found that this species also has sexually dimorphic UV color vision. To identify the genetic basis of this trait, we built a reference-grade genome assembly of H. charithonia. We discovered that one duplicate, UVRh1, is present on the W chromosome, making it obligately female-specific. We employed gDNA PCR assays of UVRh1 across the Heliconius genus. In species with sexually dimorphic UVRh1 mRNA expression, UVRh1 gDNA is absent in males, whereas in species with sexually monomorphic UVRh1 mRNA expression, UVRh1 gDNA is found in both sexes. The presence or absence of male UVRh1 expression across the Heliconius phylogeny supports a model where sexual dimorphism was acquired early via movement of a gene duplication to the W-chromosome. We used CRISPR-Cas9 to engineer a deletion in the UVRh1 locus in female H. charithonia and use immunohistochemistry to show that UVRh1 protein expression is absent in mutant tissue, similar to that of males. Our results show that a rare behavioral phenotype, sex-specific UV color vision, was acquired via sex chromosome gene traffic of a duplicated UV rhodopsin.